Do ETFs Increase Volatility? · 2019. 12. 15. · traded funds (ETFs) are rising steadily among the...
Transcript of Do ETFs Increase Volatility? · 2019. 12. 15. · traded funds (ETFs) are rising steadily among the...
Do ETFs Increase Volatility?
Itzhak Ben-David
Fisher College of Business, The Ohio State University, and NBER
Francesco Franzoni
University of Lugano and the Swiss Finance Institute
Rabih Moussawi
Wharton Research Data Services, The Wharton School, University of Pennsylvania
April 2014
Abstract
We study whether exchange traded funds (ETFs)—an asset of increasing importance—impact the
volatility of their underlying stocks. Using identification strategies based on the mechanical variation in
ETF ownership, we present evidence that stocks owned by ETFs exhibit significantly higher intraday and
daily volatility. We estimate that an increase of one standard deviation in ETF ownership is associated
with an increase of 16% in daily stock volatility. The driving channel appears to be arbitrage activity
between ETFs and the underlying stocks. Consistent with this view, the effects are stronger for stocks
with lower bid-ask spread and lending fees. Finally, the evidence that ETF ownership increases stock
turnover suggests that ETF arbitrage adds a new layer of trading to the underlying securities.
Keywords: ETFs, stocks, volatility, mispricing, fund flow
JEL Classification: G12, G14, G15
____________________
We are especially grateful to Robin Greenwood (AFA discussant) and Dimitri Vayanos. We thank George Aragon,
Chris Downing, Andrew Ellul, Vincent Fardeau, Thierry Foucault, Rik Frehen, Denys Glushkov, Jungsuk Han,
Harald Hau, Augustin Landier, Ananth Madhavan, David Mann, Rodolfo Martell, Albert Menkveld, Robert Nestor,
Marco Pagano, Alberto Plazzi, Scott Richardson, Anton Tonev, Tugkan Tuzun, Scott Williamson, Hongjun Yan,
and participants at seminars at SAC Capital Advisors, the University of Lugano, the University of Verona, the fourth
Paris Hedge Funds Conference, the fifth Paul Woolley Conference (London School of Economics), the eighth Csef-
IGIER Symposium (Capri), the fifth Erasmus Liquidity Conference (Rotterdam), the first Luxembourg Asset Pricing
Summit, the Geneva Conference and Liquidity and Arbitrage, the 20th
Annual Conference of the Multinational
Finance Society, and the Swedish House of Finance seminar for helpful comments and suggestions. Ben-David
acknowledges support from the Neil Klatskin Chair in Finance and Real Estate and from the Dice Center at the
Fisher College of Business. An earlier version of this paper was circulated under the title “ETFs, Arbitrage, and
Shock Propagation”.
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1 Introduction
With $2.5 trillion of assets under management globally as of October 2013,1 exchange
traded funds (ETFs) are rising steadily among the big players in the asset management industry.
This asset class is also capturing an increasing share of transactions in financial markets. For
example, in August 2010, exchange traded products represented about 40% of all trading volume
in U.S. markets (Blackrock (2011)). This explosive growth has attracted the attention of
regulators, who have begun to look at the hidden risks to which ETF investors are exposed and
the threat that ETFs pose to market stability. For example, Ramaswamy (2011) voices the
concern that ETFs may add to the buildup of systemic risks in the financial system. In addition,
the U.S. Securities and Exchange Commission (SEC) has begun to review whether ETFs play a
role in increasing volatility in the market. Regulators are wary of high frequency volatility
because it can reduce participation of long-term investors.2 Despite these concerns, there is scant
systematic evidence about the relation between ETF ownership and the volatility of the
underlying securities.
In this paper, we test whether ETFs lead to an increase in the volatility of the securities in
their baskets. We use variation in ETF ownership across stocks, as well as variation in ETF
mispricing and ETF flows, to measure the effects of ETFs on the volatility of the underlying
securities.3 Our results suggest that ETF ownership increases stock volatility through the
1 See http://www.hedgefundfundamentals.com/wp-content/uploads/2012/08/HFF_Hedge_Funds_101_10-
2013FINAL.pdf 2 In more detail, the risks to ETF investors relate to their potential illiquidity, which manifested during the Flash
Crash of May 6, 2010, when 65% of the cancelled trades were ETF trades. Also worthy of note, regulators have
taken into consideration the potential for counterparty risk, which seems to be operating in the cases of both
synthetic replication (as the swap counterparty may fail to deliver the index return) and physical replication (as the
basket securities are often loaned out). Moreover, concerns have been expressed that a run on ETFs may endanger
the stability of the financial system (Ramaswamy (2011)).
With regard to the SEC ETF-related concerns, see “SEC Reviewing Effects of ETFs on Volatility” by Andrew
Ackerman, Wall Street Journal, 19 October 2011, and “Volatility, Thy Name is E.T.F.”, by Andrew Ross Sorkin,
New York Times, October 10, 2011.
With regard to the SEC focus on short-term volatility, see the SEC Concept release No. 34-61358: “[S]hort term
price volatility may harm individual investors if they are persistently unable to react to changing prices as fast as
high frequency traders. As the Commission previously has noted, long-term investors may not be in a position to
access and take advantage of short-term price movements. Excessive short-term volatility may indicate that long-
term investors, even when they initially pay a narrow spread, are being harmed by short-term price movements that
could be many times the amount of the spread.” 3 In this paper, we label ETF “mispricing” the difference between the market price of the ETF and the Net Asset
Value of the ETF (NAV). This definition does not mean to imply that either the ETF or the NAV are correctly
priced, while the other is not. We are just complying with the standard jargon in the industry and taking a shortcut
with respect to the more cumbersome label of “discount/premium.”
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arbitrage trades between the ETF and the underlying stocks and, to a lesser extent, through the
flows into and out of ETFs.
In an efficient market, the price of an ETF should equal the price of its underlying
portfolio, up to transaction costs, because the two assets have the same fundamental value. The
fact that new shares of ETFs can be created and redeemed almost continuously facilitates
arbitrage so that, on average, the ETF price cannot diverge consistently and substantially from its
net asset value (NAV).4 However, due to their popularity among retail and institutional investors
for speculative and hedging purposes, ETFs are increasingly exposed to non-fundamental
demand shocks. If arbitrage is limited, these shocks can propagate from the ETF market to the
underlying securities.
To understand the mechanics of this effect, consider a large liquidity sell order of ETF
shares by an institutional trader. As described in the models of Greenwood (2005) and Gromb
and Vayanos (2010), arbitrageurs buy the ETF and hedge this position by selling the underlying
portfolio. If arbitrageurs have limited risk-bearing capacity, their demand is not perfectly elastic,
and they require compensation in terms of positive expected returns. Hence, the selling activity
leads to downward price pressure on the underlying portfolio. Consequently, the initial liquidity
shock at the ETF level is propagated to the underlying securities, whose prices fall for no
fundamental reason. In this sequence of events, arbitrageur activity induces propagation of
liquidity shocks from the ETF to the underlying securities.
We begin our analysis by exploring the relation between stock volatility and ETF
ownership. The majority of ETFs aim to replicate the performance of the index. Therefore, they
tend to hold stocks in the same proportion as in the index that they track. The identification
comes from the fact that variation in ETF ownership, across stocks and over time, depends on
factors that are exogenous with respect to our dependent variable of interest. Specifically, the
same stock appears with different weights in different indexes. Furthermore, the fraction of ETF
ownership in a firm depends also on the size of the ETF (i.e., its assets under management)
relative to that of the company. Thus, the variation in the fraction of stock ownership by ETFs,
across and within stocks, is largely exogenous. Throughout the study, we use this identification
4 Unlike premia and discounts in closed-end funds (e.g., Lee, Shleifer, and Thaler (1991), Pontiff (1996)),
mispricing between ETF prices and the NAV can more easily be arbitraged away thanks to the possibility of
continuously creating and redeeming ETF shares.
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strategy because it allows us to rule out effects based on fundamental information. For example,
it is possible that flows into ETFs are correlated with fundamental information regarding the
underlying stocks (e.g., sector-related news), but it is less likely that fundamental reasons
produce an effect on volatility that is stronger for stocks with higher ETF ownership, because
ETF ownership depends mechanically on factors that are unrelated to stock volatility.
Our first set of results shows that intraday volatility (calculated based on second-by-
second returns) increases with ETF ownership. For S&P 500 stocks, a one standard deviation
increase in ETF ownership is associated with a 21% standard deviation increase in intraday
volatility. The volatility also survives in daily returns. At this frequency, the effect of a one
standard deviation increase in ETF ownership is about 16% of a standard deviation of daily
volatility. The effects are generally less economically significant for smaller stocks, consistent
with ETF arbitrageurs concentrating on a subset of more liquid stocks to replicate the ETF
baskets.
We investigate the economic channels for the propagation of demand shocks from the
ETF market to the prices of the underlying securities. ETF arbitrage occurs at different
frequencies and in two different ways. First, at high frequencies, typically intraday, arbitrageurs
respond to discrepancies in the price of the ETF with respect to the NAV by taking long and
short positions in the ETF and the underlying securities. This buying and selling activity can
propagate demand shocks from the ETF price to the basket stocks. Second, ETF market makers
(Authorized Participants (APs)) create and redeem ETF shares in response to large demand
imbalances in the ETF market, which happens on 71% of the trading days in our sample, on
average. These flows, which involve the buying or selling of the underlying securities, can also
generate price pressure on the underlying basket.
Consistent with the first channel of ETF arbitrage, we document that volatility and
turnover increase on days when arbitrage is more likely to occur, that is, when the divergence
between the ETF price and the NAV (i.e., the mispricing) is large. Adhering to our identification
strategy, we show that this effect is significantly stronger for stocks with high ETF ownership.
Further supporting the arbitrage channel, we show that the volatility effect is even stronger
among those stocks for which arbitrage activity is less restricted (i.e., those with lower arbitrage
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costs). The effects are more intense for stocks with small bid-ask spreads and for those with low
share lending fees.
With regard to the creation/redemption channel, we again look at variation in ETF
ownership across stocks and find that ETF flows impact the volatility of the underlying stocks.
Our results show that stock volatility increases with flows to ETFs and that this effect is stronger
for stocks with high ETF ownership.
To further rule out the concern that our results are generated by a fundamental shock that
impacts the value of the ETFs and the underlying securities rather than by the propagation of
liquidity shocks, we examine the behavior of prices in the aftermath of arbitrage and flows.
Specifically, we look for evidence of return reversal after the initial price jump associated with
ETF arbitrage and flows. Price reversals are evidence of liquidity shocks (see, for example,
Greenwood (2005)), whereas fundamental shocks would leave prices at the new level. Our
results provide clear evidence of the reversal of the initial price shocks associated with ETF
arbitrage and flows, consistent with the conjecture that these channels allow propagation of
liquidity shocks.
The evidence of increased exposure of the stocks in the ETF baskets to liquidity shocks
would be irrelevant if, in the absence of ETFs, liquidity traders invested directly in the
underlying securities. Hence, an important question is whether the presence of ETFs increases
the basket securities’ overall exposure to liquidity trading. Our evidence suggests that this is the
case. Using the same identification as for the volatility effect, we show that stocks with higher
ETF ownership have significantly higher turnover. In particular, a one standard deviation
increase in ETF ownership is associated with an increase of 16% of a standard deviation in daily
turnover. Also, the higher turnover is linked to the same arbitrage channels that are driving the
volatility effect. This finding suggests that the high turnover clientele of ETFs is inherited by the
underlying stocks as a result of arbitrage. Also, it rules out the explanation that ETFs are merely
replacing investors that without the ETFs would trade directly in the stocks.
A few other studies discuss the potentially destabilizing effects of ETFs. Cheng and
Madhavan (2009) and Trainor (2010) investigate whether the daily rebalancing of leveraged and
inverse ETFs increases stock volatility and find mixed evidence. Bradley and Litan (2010) voice
concerns that ETFs may drain the liquidity of already illiquid stocks and commodities, especially
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if a short squeeze occurs and ETF sponsors rush to create new ETF shares. Madhavan (2011)
relates market fragmentation in ETF trading to the Flash Crash of 2010. In work that is more
recent than our paper, Da and Shive (2013) find that ETF ownership has a positive effect on the
comovement of stocks in the same basket. This result is a direct implication of our finding. We
show that ETF ownership increases stock volatility via the propagation of liquidity shocks.
Because the stocks in the same basket are going to be affected by the same liquidity shocks, their
covariance increases as a result.
More generally, this paper relates to the empirical and theoretical literature studying the
effect of institutions on asset prices. There is mounting evidence of the effect of institutional
investors on expected returns (Shleifer (1986), Barberis, Shleifer, and Wurgler (2005),
Greenwood (2005), Coval and Stafford (2007), and Wurgler (2011) for a survey) and on
correlations of asset returns (Anton and Polk (2010), Chang and Hong (2011), Greenwood and
Thesmar (2011), Lou (2011), and Jotikasthira, Lundblad, and Ramadorai (2012)). Cella, Ellul,
and Giannetti (2013) show that institutional investors’ portfolio turnover is an important
determinant of stock price resiliency following adverse shocks. Related to our empirical claim,
Basak and Pavlova (2013) make the theoretical point that the inclusion of an asset in an index
tracked by institutional investors increases the non-fundamental volatility in that asset’s prices.
The theoretical framework for the shock propagation effect that we describe is based on
the literature on shock propagation with limited arbitrage. Shock propagation can occur via a
number of different channels, including portfolio rebalancing by risk-averse arbitrageurs (e.g.,
Greenwood (2005)), wealth effects (e.g., Kyle and Xiong (2001)), and liquidity spillovers (e.g.,
Cespa and Foucault (2012)). The mechanism that most closely describes our empirical evidence
is the one by Greenwood (2005). Also related to our paper in terms of showing contagion with
limited arbitrage, Hau, Massa, and Peress (2010) find that a demand shock stemming from a
global stock index redefinition impacts both the prices of the stocks in the index and the
currencies of the countries in which these stocks trade.
The paper proceeds as follows. Section 2 provides institutional details on ETF arbitrage
and the theoretical framework for the effects that we study. Section 3 describes the data. Section
4 provides the main evidence of the effects of ETF ownership on stock volatility and turnover.
Section 5 explores the channels through which ETFs affect volatility. Section 6 concludes.
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2 ETF Arbitrage: Institutional Details and Theoretical Framework
2.1 Mechanics of Arbitrage
Exchange traded funds (ETFs) are investment companies that typically focus on one asset
class, industry, or geographical area. Most ETFs track an index, very much like passive funds.
Unlike index funds, ETFs are listed on an exchange and trade throughout the day. ETFs were
first introduced in the late 1980s and became popular with the issuance in January 1993 of the
SPDR (Standard & Poor’s Depository Receipts, known as “Spider”), which is an ETF that tracks
the S&P 500 (which we label “SPY,” from its ticker). In 1995, another SPDR, the S&P MidCap
400 Index (MDY) was introduced, and subsequently the number of ETFs exploded to more than
1,600 by the end of 2012, spanning various asset classes and investment strategies. Other popular
ETFs are the DIA, which tracks the Dow Jones Industrials Average, and the QQQ, which tracks
the Nasdaq-100.
To illustrate the growing importance of ETFs in the ownership of common stocks, we
present descriptive statistics for S&P 500 and Russell 3000 stocks in Table 1. Due to the
expansion of this asset class, ETF ownership of individual stocks has increased dramatically over
the last decade. For S&P 500 stocks, the average fraction of a stock’s capitalization held by ETFs
has risen from 0.27% in 2000 to 3.78% in 2012. The table shows that the number of ETFs in
which the average S&P500 stock appears has grown from just above 2 to about 50 during the
same period. The average assets under management (AUM) for ETFs holding S&P 500 stocks in
2012 was $5bn. The statistics for the Russell 3000 stocks paint a similar picture.
In our analysis, we focus on ETFs that are listed on U.S. exchanges and whose baskets
contain U.S. stocks. The discussion that follows applies strictly to these “plain vanilla” exchange
traded products that do physical replication, that is, they hold the securities of the basket that
they aim to track. We omit from our sample leveraged and inverse ETFs that use derivatives to
deliver the performance of the index, which represent at most 2.3% of the assets in the sector
(source: BlackRock). These more complex products are studied by Cheng and Madhavan (2009),
among others.
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Similar to closed-end funds, retail and institutional investors can trade ETF shares in the
secondary market.5 However, unlike closed-end funds, new ETF shares can be created and
redeemed. Because the price of ETF shares is determined by the demand and supply in the
secondary market, it can diverge from the value of the underlying securities (the NAV). Some
institutional investors (called “authorized participants,” APs), which are dealers that have signed
an agreement with the ETF provider, can trade bundles of ETF shares (called “creation units,”
typically 50,000 shares) with the ETF sponsor. An AP can create new ETF shares by transferring
the securities underlying the ETF to the ETF sponsor. These transactions constitute the primary
market for ETFs. Similarly, the AP can redeem ETF shares and receive the underlying securities
in exchange. For some funds, ETF shares can be created and redeemed in cash.6
To illustrate the arbitrage process through creation/redemption of ETF shares, we
distinguish the two cases of (i) ETF premium (the price of the ETF exceeds the NAV) and (ii)
ETF discount (the ETF price is below the NAV). In the case of an ETF premium, APs have an
incentive to buy the underlying securities, submit them to the ETF sponsor, and ask for newly
created ETF shares in exchange. Then the AP sells the new supply of ETF shares on the
secondary market. This process puts downward pressure on the ETF price and, potentially, leads
to an increase in the NAV, reducing the premium. In the case of an ETF discount, APs buy ETF
units in the market and redeem them for the basket of underlying securities from the ETF
sponsor. Then the APs can sell the securities in the market. This generates positive price pressure
on the ETF and possibly negative pressure on the NAV, which reduces the discount.
Creating/redeeming ETF shares has limited costs in most cases, especially for equity-
focused funds. These costs include the fixed creation/redemption fee plus the costs of trading the
underlying securities. Petajisto (2013) describes the fixed creation/redemption costs as ranging in
absolute terms from $500 to $3,000 per creation/redemption transaction, irrespective of the
number of units involved. This fee would amount to about 3.4 bps for a single creation unit in the
SPY (that is, 50,000 shares worth about $8.8 million as of October 2013), or 0.6 bps for five
creation units. During our sample period (2000–2012), share creation/redemption occurs, on
5 Barnhart and Rosenstein (2010) examine the effects of ETF introductions on the discount of closed-end funds and
conclude that market participants treat ETFs as substitutes for closed-end funds. 6 Creation and redemption in cash is especially common with ETFs on foreign assets or for illiquid assets, e.g., fixed
income ETFs.
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average, on 71% of the trading days. For the largest ETF, the SPY, flows into and out of the fund
occurred almost every day in 2012 (99.2% of the trading days).
Arbitrage can be undertaken by market participants who are not APs and without
creation/redemption of ETF shares. Because both the underlying securities and ETFs are traded,
investors can buy the inexpensive asset and short sell the more expensive one. For example, in
the case of an ETF premium, traders buy the underlying securities and short sell the ETF. They
hold the positions until prices converge, at which point they close down the positions to realize
the arbitrage profit. Conversely, in the case of an ETF discount, traders buy the ETF and short
sell the individual securities. ETF sponsors facilitate arbitrageur activity by disseminating NAV
values at a 15-second frequency throughout the trading day. They do so because the smooth
functioning of arbitrage is what brings about the low tracking error of these instruments. As a
result of the low trading costs and availability of information, arbitraging ETFs against the NAV
has become popular among hedge funds and high-frequency traders in recent years (Marshall,
Nguyen, and Visaltanachoti (2010)). ETF prices can also be arbitraged against other ETFs
(Marshall, Nguyen, and Visaltanachoti (2010)) or against futures contracts (Richie, Daigler, and
Gleason (2008)).7,8
These institutional details, with some modifications, also apply to synthetic ETFs, which
are more prevalent in Europe. These products replicate the performance of the index using total
return swaps and other derivatives. As a result, creation and redemption are handled in cash.
However, the secondary market arbitrage still involves transactions in the underlying securities.
So, the potential for propagation of demand shocks from the ETF market to the underlying
securities via arbitrage is also present among synthetic ETFs.
7 See http://www.indexuniverse.com/publications/journalofindexes/joi–articles/4036–the–etf–index–pricing–
relationship.html for a description of trading strategies that eliminate mispricing between ETFs and their underlying
securities. Also see: http://ftalphaville.ft.com/2011/05/18/572086/how-profitable-is-etf-arbitrage/. See, e.g.,
http://ftalphaville.ft.com/blog/2009/07/30/64451/statistical–arbitrage–and–the–big–retail–etf–con/ and
http://ftalphaville.ft.com/blog/2011/06/06/584876/manufacturing–arbitrage–with–etfs/. See
http://seekingalpha.com/article/68064–arbitrage–opportunities–with–oil–etfs for a discussion of a trading strategy to
exploit a mispricing between oil ETFs and oil futures. 8 To be precise, although these trading strategies involve claims on the same cash flows, they may not be arbitrages
in the strict sense because they can involve some amount of risk. In particular, market frictions can introduce noise
into the process. For example, execution may not be immediate, shares may not be available for short selling, or
mispricing can persist for longer than the arbitrageurs’ planned horizon for the trade. In the remainder of the paper,
when we refer to ETF arbitrage, we are implying the broader definition of “risky arbitrage.”
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Finally, although we limit our analysis to ETFs that track equity indexes, the arbitrage
process is an inherent characteristic of all types of ETFs. As a consequence, one should expect
the effects of ETFs that we describe in this paper to play out for types of underlying assets as
well.
2.2 Theoretical Framework
We conjecture that the arbitrage between ETFs and the securities in their baskets can
propagate a liquidity shock from the ETF market to the prices of these securities. The arrival of
liquidity shocks in the ETF market adds a new layer of non-fundamental volatility to the prices
of the basket securities. As a consequence, total volatility of the underlying securities can
increase due to ETF ownership.
We use Greenwood’s (2005) model with risk-averse market makers to explain the
channel of shock transmission that we wish to identify. The market makers in the model can be
thought of as the Authorized Participants or, more generally, the arbitrageurs in the ETF market.
We apply this model to two assets with identical fundamentals: the ETF and the basket of
underlying securities (whose market value is the NAV of the ETF). To illustrate, we imagine a
situation in which the ETF price and the NAV are aligned at the level of the fundamental value
of the underlying securities, as in Figure 1a. Then, a non-fundamental shock, such as an
exogenous increase in demand, hits the ETF market. This type of shock could happen, for
example, if a large institution receives inflows and scales up its existing ETF allocation.
Arbitrageurs absorb the liquidity demand by shorting the ETF. Because they are risk averse, the
arbitrageurs require compensation for the (negative) inventory in the ETF that they are holding.
Hence, the ETF price has to rise (Figure 1b). At the same time, to hedge their short ETF position,
arbitrageurs take a long position in the securities in the ETF basket. This buying activity puts
upward pressure on the prices of the basket securities, as in Figure 1c. Eventually, as in the last
period of Greenwood’s (2005) model, prices revert back to fundamentals (Figure 1d).
In this sequence of events, shock transmission results from the trading of risk-averse
investors who require compensation for holding assets in the two markets. To provide the
investors with the required risk premium, prices have to adjust in both markets.
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In Greenwood’s (2005) model, the long and short hedging trades happen simultaneously
(i.e., the movements in Figures 1b and 1c happen at the same time). Moreover, given that there is
a unique market maker, two assets with identical payoffs always end up having the same price,
and no discrepancy between the ETF price and the NAV can be present at any time. As a result,
a strict adherence to the model would prevent the ETF price from ever deviating from the NAV.
Although this simple theoretical framework allows us to describe the mechanism for liquidity
shock transmission, we need a richer model to capture the fact that in reality the ETF price and
the NAV can diverge for some time.
Cespa and Foucault (2012) provide a useful framework with multiple investor classes and
some degree of market fragmentation. They assume three types of traders: liquidity demanders,
who submit market orders in one of two markets, and two types of liquidity suppliers: market
makers, who are specialized in one asset class, and cross-market arbitrageurs, who trade
securities in both markets. Arbitrageurs respond to misalignments in the prices of the assets in
the two markets. The model is static in the sense that all investor classes trade in the same period.
As a result, even with this model, price discrepancies between two identical assets cannot
emerge.
One can conceive a dynamic extension of the Cespa and Foucault (2012) framework in
which trade occurs sequentially. In the first period, there is a liquidity shock in one of the two
assets that is accommodated by market makers via a price adjustment. In the next period, the
market makers for the second asset observe the price realization of the first asset and adjust their
own price. Cross-market arbitrageur trading also occurs in the second period, bringing about
price convergence between the two assets. In this dynamic framework, the prices of two identical
assets can temporarily differ (in the first period). In this modified framework, arbitrageurs’ risk
aversion and hedging trades are still crucial for the transmission of liquidity shocks between the
two markets.
The mechanism that we have just described generates predictions that partly overlap with
those from an alternative scenario positing gradual price discovery after a shock to fundamentals.
According to this alternative view, prices behave similarly to the description in Figure 1, but the
trigger is a fundamental shock rather than a liquidity shock. Specifically, it is possible that price
discovery takes place in the ETF market first, for example, because it is more liquid. Then, when
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fundamental information gets to the market, ETF prices adjust immediately, but the underlying
securities’ prices remain temporarily fixed (“stale pricing”). The slow adjustment of the NAV
generates a sequence of price moves that resembles those in Figure 1. This situation is illustrated
in Figure 2. The initial equilibrium (Figure 2a) is perturbed by a shock to the fundamental value
of the ETF components (Figure 2b). If price discovery takes place in the ETF market, the ETF
price moves first (Figure 2c) and the prices of the underlying securities move with a delay
(Figure 2d).
Because stale pricing could be a relevant phenomenon, especially for the more illiquid
underlying securities, we need to show that liquidity shock propagation does take place. The
crucial distinction between the liquidity shock propagation mechanism that we wish to identify
(Figure 1) and the alternative scenario with stale pricing (Figure 2) is that non-fundamental
shocks induce a reversal in stock prices (Figure 1d). This does not happen if the initial shock is a
fundamental one, as in the price discovery scenario. Hence, in our empirical analysis, we provide
evidence of price reversal for the underlying securities to corroborate our conjecture that
arbitrage trading can transfer liquidity shocks across markets.
The claim that ETF ownership increases volatility faces the challenge of clearly
specifying the counterfactual. Our view is that in the absence of ETFs, the underlying stocks
would be less affected by liquidity shocks because of the lower incidence of arbitrage trading.
Specifically, we posit that ETFs attract a new clientele with significantly higher turnover than the
original investors in the underlying stocks. Theoretical support for our conjecture comes from
Amihud and Mendelson (1986) who posit that investors with shorter holding periods self-select
into assets with lower trading costs. In the specific case of ETFs, this theory implies that the low
transaction costs of these securities attract a new clientele of high-turnover investors. These
traders impound liquidity shocks at a higher frequency in the ETF prices. In our story, these
shocks are then transmitted to the underlying securities via arbitrage. 9
A different view is that, if ETFs were not available, the same investors would directly
trade the underlying securities. According to this argument, ETFs are simply another vehicle
through which the same clientele trades in the underlying securities. The implication of this logic
9 Because we claim that the low trading costs of ETFs attract high-frequency traders, our stance is analogous and
symmetric to the argument that transaction taxes can deter short-term investors from affecting asset prices (Stiglitz
(1989), Summers and Summers (1989)). The literature is split on this issue (Jones and Seguin (1997)).
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is that, in the absence of ETFs, the non-fundamental shocks would hit directly the underlying
securities’ prices and their volatility would still be impacted. A prediction of this argument is that
ETFs are a replacement for the underlying securities, as far as trading volume is concerned.
Grossman (1989) makes a related point about futures. He argues that the volatility of the prices
of the underlying assets would be even higher in the absence of futures, because future markets,
being more liquid, are better suited to absorb non-fundamental shocks.
Ultimately, whether low transaction costs of ETFs attract a clientele of high-frequency
traders that increase the exposure of the underlying securities to non-fundamental shocks is an
empirical question. A prediction of our claim, which separates it from the alternative view, is that
ETF ownership is related to higher turnover in the underlying securities. This consideration
motivates us to use turnover as an additional dependent variable, besides volatility, in our
empirical tests. Specifically, using an identification strategy based on the exogenous variation in
ETF stock ownership, we intend to show that the presence of ETFs is related to higher stock
turnover. Also, to further support our claim, the empirical analysis aims to draw a positive link
between stock turnover and proxies for ETF arbitrage activity.
3 Data
We use Center for Research in Security Prices (CRSP), Compustat, Bloomberg, and
OptionMetrics data to identify ETFs traded on the major U.S. exchanges and to extract returns,
prices, and shares outstanding. To identify ETFs, we first draw information from CRSP for all
1,554 securities that have the historical share code of 73, which exclusively defines ETFs in the
CRSP universe. We then screen all U.S.-traded securities in the Compustat XpressFeed and
OptionMetrics data, identifying ETFs using the security-type variables, and merge this sample
with the CRSP ETF sample.10
Our initial sample consists of 1,883,124 daily observations for
1,673 ETFs between 1993 and 2012. Because very few ETFs traded in the 1990s, we restrict the
sample to the 2000–2012 period. Among other statistics, Table 1 reports stock-level averages of
the number of ETFs and of the AUM of the ETFs, broken down by the S&P 500 and Russell
3000 universes. The table shows that the number of ETFs holding the average stock increased
10
Note that at the time of the first draft of this paper in 2011, the CRSP-Compustat merged product did not correctly
link ETF securities in the CRSP and Compustat universes. For this reason, we use historical CUSIP and ticker
information to map securities in the CRSP, Compustat, and OptionMetrics databases.
14
dramatically since the year 2000, for both S&P 500 and Russell 3000 stocks. In 2000, there were
two ETFs per stock in both universes, on average, compared to 49 and 27 in 2012 for the average
S&P 500 and Russell 3000 stock, respectively. Furthermore, as the total market capitalization of
ETFs increased, the average ownership of ETFs per stock increased from 0.3% in 2000 to 3.8%
in 2012.
We use total shares outstanding at day-end to compute the daily market capitalization of
each ETF and to measure the net share creations/redemptions of each ETF at the daily level.
Because CRSP shares outstanding figures are stale during the month, we assessed the accuracy
of three databases that provide shares outstanding data at a daily frequency: Bloomberg,
Compustat, and OptionMetrics. Thanks to direct validation by BlackRock, we concluded that
Bloomberg is more timely in updating ETF shares outstanding when newly created or redeemed
shares are cleared with the Depository Trust & Clearing Corporation (DTCC). On many
occasions, Compustat and OptionMetrics shares outstanding data lag Bloomberg by up to three
and sometimes five days. Therefore, Bloomberg is our primary source for shares outstanding and
the related net flow measures. We use Compustat and OptionMetrics to complement the ETF
series when there are gaps in the Bloomberg data.
We then obtain net asset value (NAV), in addition to fund styles (objectives) and other
characteristics, from the CRSP Mutual Fund and Morningstar databases. Our initial ETF sample
consists of 1,673 ETFs, many of which invest in various asset classes and non-U.S. securities. To
examine how arbitrage amplifies liquidity shocks to underlying securities through
creating/redeeming ETF shares and secondary market arbitrage, we restrict our sample to ETFs
that invest primarily in U.S. domestic equity stocks, because they are not plagued with stale
pricing issues (global equity or bond ETFs) or other issues (short bias, volatility, and futures-
based ETFs, commodities, etc.). Therefore, we exclude leveraged, short equity ETFs, and all
ETFs that invest in international or non-equity securities, or in futures and physical commodities.
We also eliminate hedge and long/short ETFs as well as dedicated short bias funds and focus on
plain vanilla U.S. domestic long equity ETFs. To do so, we use both CRSP Style Codes and
Lipper prospectus objective codes in the CRSP Mutual Fund Database to restrict our sample to
the fund objectives that span broad-based U.S. Diversified Equity funds and U.S. sector ETFs
that invest in equities (e.g., U.S. companies investing in oil and natural resources vs. those
15
investing in oil or commodity futures).11
We end up with 660 U.S. equity ETFs, for which we
obtain quarterly holdings information using Thomson-Reuters Mutual Fund holdings database.
ETFs are subject to Investment Company Act reporting requirements, and similar to mutual
funds, they have to disclose their portfolio holdings at the end of each fiscal quarter.12
We use
these data to align ETF ownership every month using the most recently reported holdings. Then,
for every stock, we sum the total ownership by various ETFs to construct our ETF holdings
measure.
We use Trade and Quote database (TAQ) data to compute stock-level volatility at a daily
frequency from second-by-second data. For each stock, we compute a return in each second
during the day using the last trade price at the end of each second during market hours (between
9:30 am and 4:00 pm). Then, we compute the standard deviation of those second-by-second
returns as the intraday volatility measure.13
Daily turnover is computed as CRSP volume divided
by shares outstanding.
Using TAQ, we extract the ETF end-of-day prices exactly at 4:00 pm to ensure that ETF
prices and the underlying NAV are computed at the same time. Some ETFs are traded until 4:15
pm (Engle and Sarkar (2006)), but the major U.S. stock markets close at 4:00 pm; thus, we use
4:00 pm ETF prices drawn from the intraday TAQ feed as the last trade in the ETF at or before
4:00 pm. Then, we compute ETF mispricing as the difference between the ETF share price and
the NAV of the ETF portfolio at day close. Mispricing is expressed as a fraction of the ETF
price. Part of our analysis is carried out at a monthly frequency. To this end, we compute
volatility at a monthly frequency from the standard deviation of daily returns within the month.
11
The Lipper Asset Code is not sufficient to accurately filter for U.S. domestic equity funds, because the Equity
Funds code comprises of a wide array of U.S. and global funds that implement various direct investment or
alternative/inverse strategies. Instead, we use Lipper Objective Code classifications that are assigned by Lipper to a
specific population of equity funds and are based on how the fund invests by looking at the actual holdings of the
fund to determine market cap and style versus a benchmark. We restrict our sample to the following Lipper
Objective Codes: Board Based U.S. Equity: S&P 500 Index Objective Funds, Mid-Cap Funds, Small-Cap Funds,
Micro-Cap Funds, Capital Appreciation Funds, Growth Funds, Growth and Income Funds, and Equity Income
Funds ('CA' ,'EI' ,'G' ,'GI' ,'MC' ,'MR' ,'SG' ,'SP' respectively). We also include Sector Funds that invest in U.S.
companies: Basic Materials, Consumer Goods, Consumer Services, Financial Services, Health/Biotechnology,
Industrials, Natural Resources, Real Estate, Science and Technology, Telecommunications, Specialty/Miscellaneous
Funds, and Utilities (BM, CG, CS, FS, H, ID, NR, RE, TK, TL, S, and UT, respectively). 12
We find that Thomson Mutual Fund Ownership data is more reliable and more complete than CRSP Mutual Fund
Holdings until mid-2010. 13
We also compute intraday volatility using intraday returns based on NBBO midpoints, and the results are similar.
16
We extract stock lending fees from the Markit Securities Finance (formerly Data
Explorers) database. The database contains about 85% of the OTC security lending market, with
historical data going back to 2002. In constructing the aggregate security loan fee, Markit
extracts the agreed fees from contract-level information and constructs a fee value that is the
volume weighted average of each contract-level security loan fee. We use the variable that
reports the average lending fee over the prior seven days.
Table 2 reports summary statistics for the variables that we use in the regressions. Panel
A presents summary statistics for the day-stock level sample. Panel B presents summary
statistics for the month-stock level sample. Panel C presents a correlation table for the variables
in the daily-frequency sample. We further describe these variables in later sections.
4 The Effect of ETF Ownership on Volatility and Turnover
4.1 Identification
Our objective is to test whether ETF ownership leads to an increase in the volatility of the
underlying securities. To this end, we exploit the variation in ETF ownership across stocks and
over time.
ETF ownership of stock i at time t is defined as the sum across ETFs holding the stock of
the dollar value of holdings divided by the stock’s capitalization. We write this as
∑
(1)
where J is the set of ETFs holding stock i; is the weight of the stock in the portfolio of ETF
j; and is the assets under management of ETF j.
From Equation (1), it appears that variation in ETF ownership across stocks and over
time primarily comes from three sources. First, stocks are typically part of multiple indices (e.g.,
a stock might be part of the S&P 500, the S&P 500 Value, the Russell 3000, and sector indices).
Second, there is variation in ETFs’ assets under management; thus, the dollar amount that the
ETFs invest across stocks varies. Third, there is variation in weighting schemes. The S&P 500
and many other indexes are capitalization-weighted, but the Dow Jones is price-weighted. Our
17
identifying assumption is that variation in ETF ownership resulting from these three sources is
exogenous with respect to our dependent variables of interest, stock volatility and turnover,
especially when stock-level controls (such as market capitalization and liquidity) are included in
the regression. Conditioning on a given universe, such us the S&P 500 and the Russell 3000,
characteristics like volatility and turnover play no role in determining the sub-index to which a
stock belongs (e.g., S&P 500 Growth or Value or sector indices). Also, investors’ demand for
ETFs, which determines AUM, and the way in which indices are calculated are exogenous with
respect to the dependent variables. Given these considerations, we believe that the identifying
assumption is well founded.
To further ensure that our results are driven by exogenous variation in ETF ownership, in
our preferred specifications we control for stock-level fixed effects. In these regressions, the
variation in ETF ownership is for the same stock over time, and we control for unobservables
that are potentially correlated with the dependent variable.
Based on Equation (1), we can anticipate that there is a mechanical negative correlation
between ETF ownership and stock capitalization. This can happen if the weights at the
numerator do not grow fast enough with capitalization to compensate for the increase in the
denominator. The summary statistics in Table 2 confirm that ETF ownership and market
capitalization are unconditionally negatively correlated. Considering that market capitalization is
negatively correlated with volatility (Table 2), which is one of the main dependent variables of
interest in our analysis, the negative relation between ownership and size could induce a spurious
positive relation between ownership and volatility. To filter out this mechanical link, we include
controls for market capitalization in all of our analyses.
Overall, these arguments suggest that there is exogenous variation in ETF ownership that
can be used to identify the effect of ETFs on volatility. We isolate this exogenous component of
ETF ownership by controlling for stock size and fixed effects.
4.2 ETF Ownership, Intraday Volatility, and Turnover
In line with regulators’ concerns that the recent wave of financial innovation may affect
high-frequency volatility, we start by looking at whether ETF ownership has an impact on
18
intraday volatility. Using daily stock-level observations, we regress intraday volatility, computed
using second-by-second returns from TAQ, on prior-day ETF ownership as well as on prior-day
controls for size and liquidity. The controls for liquidity are the inverse of the stock price, the
Amihud (2002) measure of price impact, and the bid-ask spread expressed as a percentage. We
also include day fixed effects in all regressions and add stock fixed effects in even numbered
columns. Standard errors are clustered at the stock level.
Because we argue that the additional volatility coming from ETF ownership stems from
trading by a high-turnover clientele, we also study the effect of ETF ownership on stock
turnover. In specifications that mirror those for volatility, we use stock turnover as the dependent
variable, computed as the CRSP dollar volume divided by market capitalization.
First, we limit our sample to the S&P 500 stock universe. The volatility results are
presented in Table 3, Columns (1) and (2). The regressions show that intraday volatility is
significantly related to ETF ownership. In light of the identification strategy described above, we
assert that these estimates establish a causal link between ETF ownership and stock volatility.
Column (2) indicates that a one standard deviation increase in ETF ownership is associated with
higher volatility by 19% of a standard deviation.14
The effect seems economically important.
In Columns (3) and (4) of Table 3, we explore whether ETF ownership also affects stock
turnover. The estimates reveal a positive and significant relation between ETF ownership and
turnover. Column (4) shows that a one standard deviation increase in ETF ownership is
associated with higher turnover by about 19% of a standard deviation.15
Again, the effect seems
economically large and supports the view that ETFs attract a high-turnover clientele.
In Columns (5) to (8), we repeat these tests for the sample of Russell 3000 stocks. After
controlling for stock fixed effects, we again find a significant relation between ETF ownership
and stock volatility. In both turnover specifications, the estimates are statistically significant. In
this sample, however, the effects are substantially smaller than for large stocks. For example,
Column (6) shows that a one standard deviation increase in ETF ownership raises intraday
volatility by about 8% of a standard deviation. Quite plausibly, arbitrageurs are less likely to rely
14
(0.243 * 0.014) / 0.018 = 0.1890. 15
(11.631 * 0.014) / 0.853 = 0.1909.
19
on small stocks to replicate ETF baskets. Hence, small stocks’ prices and volume are less
impacted by ETF ownership.
The results in Table 3 provide our primary evidence that volatility and turnover are
significantly related to ETF ownership. Because of our identification strategy, we consider
variation in ETF ownership as exogenous with respect to the dependent variables, especially
after controlling for stock characteristics and fixed effects. Hence, we feel that we can attribute a
causal interpretation to the estimates in Table 3. Overall, this analysis helps to establish that
ETFs are catalysts for demand shocks that ultimately affect the underlying securities.
4.3 Effects of ETF Ownership on Daily Return Volatility
Our results in Table 3 show that ETF ownership is associated with higher return volatility
within the day. However, a legitimate concern is that while it is possible that ETFs affect the
microstructure of trading for the underlying securities, these effects are washed out over longer
horizons. To examine this possibility, we study whether the effects that we identify are a short-
lived phenomenon (e.g., induced by high-frequency traders) or whether these effects also exist at
frequencies that are relevant for long-term investors. We define our explanatory variables at the
monthly frequency and construct the dependent variable, volatility, using the daily return
observations within a month. In this way, we can study whether ETF ownership impacts the
volatility of daily returns.
Table 4 shows a regression of daily stock volatility in a given month on the average ETF
ownership of the stock within the month. We use stock-level controls to absorb effects that could
induce a mechanical link between ownership and our dependent variable. To this purpose, we
include (the logarithm of) the market capitalization of the stock as well as the same controls for
liquidity as in Table 3. We cluster standard errors both at the date and the stock levels. In
addition, date and stock fixed effects are included in all the specifications.
In Columns (1) to (3), we limit the sample to S&P 500 stocks, and in Columns (4) to (6),
we extend it to Russell 3000 stocks. The regressions in Columns (1) and (4) show that stock
volatility is positively related to ETF ownership and that the effect is stronger for large stocks. In
Column (1), a one standard deviation increase in stock ownership for S&P 500 stocks (1.44%) is
20
associated with a 20 bps increase in daily volatility, which represents 16% of the standard
deviation of the dependent variable.16
The economic significance is therefore large. Extending
the universe to smaller stocks (Column (4)), the effect is diluted, amounting to about 5% of a
standard deviation.17
This finding confirms the evidence for intraday volatility in Table 3.
Next, we preview the arbitrage channels through which ETF ownership affects stock
volatility. These effects are studied in more detail in Section 5. In Table 4, Columns (2) and (5),
the explanatory variable is the volatility of stock-level mispricing within a given month.
Mispricing is the value-weighted average of the mispricing of the ETFs holding the stock. The
weights are proportional to the dollar holdings of the stock by a given ETF. Rather than
averaging daily stock-level mispricing, which would conceal the fact that both positive and
negative mispricing provides arbitrage opportunities, we compute its volatility, which treats
positive and negative mispricing equally.18
This variable is meant to capture the extent of
arbitrage opportunities emerging during a month. In both samples of stocks, our proxy for
arbitrage opportunities has a positive and significant relation with stock-level volatility.
Consistent with the effects of ETF ownership (Columns (1) and (4)), we find a stronger effect in
the sample of large stocks (Column (2)) than smaller stocks (Column (5)). For S&P 500 stocks, a
one standard deviation increase in the explanatory variable (0.003) raises stock volatility by
about 22% of a standard deviation.19
The effect is smaller at 5.2% of a standard deviation in the
sample of Russell 3000 stocks.20
Especially among large stocks, the economic significance of the
impact on stock volatility of the proxy for ETF arbitrage seems large even at this lower
frequency.
Our second measure of arbitrage focuses more closely on the creation/redemption
channel. In Columns (3) and (6), the explanatory variable is the volatility of stock-level flows,
which are the sum of ETF flows (that is, the dollar value of creations/redemptions, scaled by the
lagged ETF market capitalization) allocated to a given stock across all the ETFs holding the
stock, as a fraction of the stock’s market capitalization. Again, we take the volatility of this
variable to avoid averaging positive and negative flows (the sum of absolute flows gives similar
16
(0.144 * 1.440) / 1.290 = 0.1607. 17
(0.041 * 1.730) / 1.490 = 0.0476. 18
We obtain similar results if we use the average of absolute mispricing as the explanatory variable. 19
(94.223 * 0.003) / 1.290 = 0.2190. 20
(25.973 * 0.003) / 1.490 = 0.0522.
21
results). The results are consistent with our prediction that the creation/redemption activity exerts
pressure on the prices of the underlying securities, which translates into higher stock volatility.
Like in the previous regressions, the impact of flows on volatility is stronger for S&P 500 stocks,
amounting to 13% of a standard deviation for a one standard deviation increase in the
explanatory variable. For Russell 3000, the effect is weaker, at 3.4% of a standard deviation.21
Overall, the evidence suggests that the effect of ETFs on volatility persists beyond the
intraday horizon. The daily volatility we study in this section is relevant for investors, such as
mutual funds, that do not trade at high frequencies but still reallocate their portfolio on a daily
basis. The next section extends the analysis of the arbitrage channel and the impact of ETF
ownership on stock volatility.
5 Exploring the Arbitrage Channel
As discussed in Section 2, we posit that ETFs propagate demand shocks to the underlying
securities. Consequently, a new layer of liquidity shocks hit the basket securities. In Section 4,
we provide evidence consistent with this conjecture by showing that stocks with higher ETF
ownership display higher volatility and turnover. We also show that both the ETF average
mispricing and flows within a month affect daily stock volatility. In this section, we look more
closely at the arbitrage channel.
21
For S&P500 stocks: (3.757 * 0.045) / 1.290 = 0.131; for Russell 3000 stocks: (0.939* 0.055) / 1.490 = 0.034.
22
5.1 Stock Volatility, ETF Ownership, and Arbitrage Activity
Arbitrage occurs in two ways. At high frequencies, arbitrageurs take long and short positions in
ETFs and the underlying baskets and wait for price convergence. At lower frequencies,
Authorized Participants create and redeem ETF shares to profit from mispricing. In both cases,
arbitrageurs and APs react to price discrepancies between the ETF price and the NAV (ETF
mispricing). Hence, in our first set of tests, we use stock-level mispricing as a proxy for arbitrage
trading. Then, focusing more closely on AP activities, we also measure arbitrage trading using
creation and redemption of ETF shares. Thus, in a second set of tests, we use stock-level ETF
flows as a proxy for arbitrage activity.
5.1.1 Arbitrage Trades following ETF Mispricing
Stock-level absolute mispricing is the value-weighted average of the absolute value of the
mispricing of the ETFs holding the stock. The absolute value is motivated by the fact that
arbitrage responds to both positive and negative levels of mispricing. The weights are
proportional to the fraction of the stock owned by each ETF (i.e., ETF ownership). For stock i on
day t, mispricing is defined as
( ) ∑ | |
∑
(2)
where J is the set of ETFs holding stock i at time t, and is the difference between
the ETF price and its NAV, scaled by the ETF price and measured using closing prices.
Then, our regression specification is
( )
( )
(3)
We run a similar specification using stock turnover as the dependent variable. We use the
same controls as in Table 3, and standard errors are clustered at the stock level.
Our variable of interest in equation (3) is the interaction between ownership and
mispricing. We posit that because of arbitrage, the effect of ownership on volatility and turnover
23
is stronger for stocks that are held by ETFs with larger mispricing. We use lagged end-of-day
mispricing to test this supposition because it proxies for arbitrage that takes place during day t.
Using day-t mispricing instead does not materially affect the results.
Table 5, Panel A, presents the regressions. In Column (1), we observe that intraday
volatility increases with the absolute ETF ownership. As expected, the effect is significantly
stronger for stocks with high ETF mispricing, which is reflected in the slope on the interaction
between the absolute ETF mispricing and ETF ownership. For stocks that have close to zero ETF
ownership, the effect of ETF mispricing is minimal. A one standard deviation increase in
abs(ETF mispricing) is associated with an increase of 0.4% of a standard deviation in volatility.22
However, if ETF ownership is at its mean (1.9%), the effect is much larger: a one standard
deviation increase in abs(ETF mispricing) is associated with an increase of 85.4% of a standard
deviation in volatility.23
The effect on intraday turnover is large as well (Column (2)). In the absence of ETF
ownership, a one standard deviation increase in lagged absolute mispricing is associated with
higher intraday turnover by 0.3% of a standard deviation.24
However, when ETF ownership is at
its mean, intraday turnover is higher by 26.3% of a standard deviation.25
Although the results for the S&P 500 sample are very strong both statistically and
economically, the corresponding results for the Russell 3000 are not significantly different from
zero, confirming the prior evidence of a weaker effect on smaller stocks. Overall, these results
suggest that the arbitrage of ETF mispricing is an important channel to explain the impact of
ETF ownership on volatility, especially for large stocks.
5.1.2 Arbitrage Activity by APs
Next, we more directly test the impact of ETF arbitrage through creation and redemption
activity by APs. We measure stock-level flows using the following definition:
22
0.006 * 0.013 / 0.018 = 0.0043. 23
(0.006 * 0.013 + 42.035* 0.013 * 0.019) / 0.018 = 0.8543. 24
(0.207 * 0.013) / 0.853 = 0.0032. 25
(0.207 * 0.013 + 896.893 * 0.013 * 0.019) / 0.853 = 0.2628.
24
( ) ∑
∑ |
|
∑
(4)
For each stock i and day t, we sum the product of the percentage of flows into the ETFs that own
the stock and the percentage ownership of the ETF in the stock. For example, if ETF j
experiences a flow of 1% and owns 10% of stock i, the stock is likely to experience a demand for
1% * 10% = 0.1% of its shares. Because both positive (share creation) and negative (share
redemption) flows represent arbitrage activity, in equation (4) we take the absolute value of the
flows.
Our specification resembles equation (3), but we replace ( ) with
( ). Table 5, Panel B, presents the results of the regressions. We first
consider the S&P 500 sample (Columns (1) and (2)). The main effect of ETF ownership on stock
volatility (Column (1)) remains positive and significant. Moreover, the effect is magnified for
stocks with higher flows. When ETF ownership is at its mean, a one standard deviation increase
in absolute ETF flows translates into volatility that is higher by 3.7% of a standard deviation.26
The effect of ETF ownership interacted with flows on stock turnover is similar in
magnitude and significance (Column (2)). For the mean value of ETF ownership, a one standard
deviation increase in absolute ETF flows is associated with turnover higher by 6.6% of a
standard deviation.27
Columns (3) and (4) present similar regressions for the Russell 3000 sample. Here, the
results are in the same direction as in the S&P 500 sample. They are weaker for volatility and
stronger for turnover. For stocks at the mean level of ownership, a one standard deviation
increase in absolute ETF flows translates into an increase of 1.2% of a standard deviation in
intraday volatility28
and of 12.3% of a standard deviation in intraday turnover.29
In sum, our findings support the conjecture that ETF ownership also increases volatility
and turnover through the channel of share creation/redemption by market makers (APs). The
26
(-0.009 * 0.013 + 3.197 * 0.019 * 0.013) / 0.018 = 0.0373. 27
(-0.090 * 0.013 + 232.101 * 0.019 * 0.013) / 0.853 = 0.0534. 28
(0 * 0.080 + 0.141 * 0.021 * 0.080) / 0.020 = 0.0118. 29
(-0.129 * 0.080 + 70.306 * 0.021 * 0.080) / 0.875 = 0.1227.
25
importance of this channel, however, seems smaller in magnitude than the effect originating
from ETF mispricing arbitrage.
5.2 Evidence of Price Reversals for the Underlying Stocks
Our conjecture is that arbitrage trades between ETFs and their replicating portfolios are
able to cause an increase in non-fundamental volatility of the underlying stocks. To corroborate
this prediction, it is crucial to provide evidence consistent with the propagation of non-
fundamental shocks by ETF arbitrage.
The alternative scenario to our conjecture is one in which trading in the underlying
securities is motivated by fundamental information. The fundamental news is impounded in the
ETF price first and then, with a delay, into the prices of the underlying securities (stale pricing).
This view can also explain the observed correlation between arbitrage trades and stock volatility
if the new information generates both increased trading activity and higher volatility.
In Section 2.2, we argue that a key distinction between these two scenarios is whether,
following the initial price impact of arbitrage trades, stock prices revert toward the initial
equilibrium (as in Figure 1) or whether they remain at the new level (as in Figure 2). In the first
case, consistent with our conjecture, one can conclude that the price change following arbitrage
trades is, at least in part, due to a non-fundamental shock.
As in Section 5.1, we use mispricing and flows to identify arbitrage trades. In this case,
however, the sign of these variables matters for the direction of the price impact and the
subsequent reversal. Specifically, positive mispricing (i.e. an ETF premium) triggers purchases
of the underlying stocks. Hence, on the first day in which arbitrage trades occur, we expect a
positive price impact on the underlying stocks. In the next days, we expect a reversal if the
arbitrage-triggering shock is non-fundamental (as in Figure 1). Similarly, positive flows (share
creation) involve purchases of the underlying securities. Hence, on the first day, we expect a
positive price impact and a reversal in the following days.
To test this conjecture, we first use mispricing as a signal for arbitrage trades and adopt
the following specification:
26
( )
(5)
where ( ) is the stock return measured between days to . When , we use
the returns on the same day that the arbitrage trades take place. In this case, we expect to be
positive. To test for reversal, we let and (with K = 5, 10, 20 days) and
expect to be negative and significant. We use day-stock level observations and cluster the
standard errors at the stock level to control for the autocorrelation of residuals induced by
overlapping observations for multiday returns.
The evidence in Table 6, Panel A, is broadly consistent with our expectation that
arbitrage propagates non-fundamental shocks. In Column (1), we observe that the first-day effect
of ETF mispricing is positive and significant, and it is magnified by ETF ownership. The
magnitude of the effect can be calculated as follows. For the S&P 500 sample (Column (1)), a
one-standard deviation move in ETF mispricing, for stocks with the mean level of ETF
ownership (0.019), brings about an increase in daily returns of 0.085%.30
This seems like a large
effect given that the mean daily return in the sample is 0.053%.
For completeness, we report the estimate for Russell 3000 stocks (Column (5)). In this
sample, the main effect of mispricing is not significant, while the sign on the interaction between
ownership and mispricing is actually negative, which confirms the evidence from the previous
sections that ETF arbitrage plays a less significant role in this universe.
In the days following the trade, we expect prices to revert. For example, at times when
the ETF trades at a premium relative to the NAV, after the initial positive impact on the NAV,
we expect to see a downward drift in stock prices. This prediction is confirmed in Columns (2) to
(4). For windows of 5 to 20 days, stock returns are negatively correlated with the ETF
mispricing, as predicted. This correlation is more negative for stocks with higher ETF ownership.
The economic magnitude of the reversal is large. Consider the month-long window
(Column (4)) for the S&P 500 sample. A one standard deviation increase in mispricing at ,
for stocks with ETF ownership at its mean (0.019), is associated with lower returns of –0.344%
30
(1.043 * 0.012 + 321.266 * 0.019 * 0.012) = 0.0857%.
27
over the next trading month.31
Given that mispricing is persistent, this large reversal, exceeding
in magnitude the first day price impact, can be the result of the unwinding of the price impacts
from days prior to day . For the Russell 3000 (Column (8)), the effect is close to zero and is
statistically insignificant, which is consistent with the evidence from the prior tables of a weaker
effect of flows on smaller stocks.
We also measure the behavior of prices following the redemption/creation of ETF units
by APs, which is the other channel through which arbitrage can propagate non-fundamental
shocks, according to our conjecture. Inflows into ETFs emerge if APs purchase the underlying
securities and convert them into ETF units. ETF outflows result from APs converting ETF units
into the underlying securities, which are sold in the market. Because the price impact on the
underlying stocks is different as a function of the direction of the flows, the sign of the flows is
now important and the explanatory variable is net flows, as opposed to absolute flows.
Table 6, Panel B, estimates the one- and multiple-day price reaction to ETF flows.
Focusing on S&P 500 stocks, consistent with our conjecture, an increase in flows on day
generates positive pressure on the same day (Column (1)), and it reverts in the following days
(Columns (2) to (4)). From Column (1), a one-standard deviation increase in ETF flows, for
stocks at the mean level of ownership, is associated with higher returns by 0.01%.32
Then,
comparing the first-day price impact in Panels A and B of Table 6, we conclude that the effect of
flows is significant, but less economically large than the effect of mispricing arbitrage, which is
consistent with the evidence in Table 5.
Column (5) of Panel B, Table 6, shows that the first-day impact for Russell 3000 stocks,
contrary to our expectation, is negative. This finding confirms that the evidence for smaller
stocks is less robust. Also possible, because of the lower liquidity in this universe of stocks, APs
start trading the underlying securities a few days before creation/redemption. As a result, on day
, the price impact has already started to revert.
In the days following , prices revert, consistent with our conjecture. For the S&P
500 sample, when ETF ownership increases from zero to the mean level, a one-standard
31
(–1.671 * 0.012 – 1421.138 * 0.019 * 0.012) = –0.3440%. 32
(0.255 * 0.019 + 16.245 * 0.019 * 0.019) = 0.0107%.
28
deviation increase in ETF flows is correlated with next-20-day returns of –0.156%.33
Columns
(5) to (8) present the effects for Russell 3000 stocks. Here, the reversal effect is also significant,
but smaller in magnitude.
In sum, we show that stocks prices follow a patter which is consistent with arbitrage
having a role in propagating non-fundamental shocks. Our results show that the effect is stronger
for S&P 500 stocks than for Russell 3000 stocks. One potential reason for the less significant
role of arbitrage trades in the Russell 3000 universe is that smaller stocks are subject to greater
limits of arbitrage. We explore this possibility in the next sub-section.
5.3 Limits to Arbitrage
To validate the conjecture that the effects we identify operate through the arbitrage
channel, we introduce interactions with proxies for limits to arbitrage. Our prior is that arbitrage
trading should be less important when limits to arbitrage are more binding. We use two proxies
for limits to arbitrage: the stock-level bid-ask spread and stock lending fees.
Because ETF arbitrage involves a roundtrip transaction in the stock, a large stock-level
bid-ask spread reduces the profitability of arbitrage trades and the incidence of arbitrage trading
in a given stock. The prediction is, therefore, that the volatility and turnover of stocks with high
bid-ask spreads are less sensitive to proxies of ETF arbitrage. In Table 7, Panel A, we split the
sample according to the median percentage bid-ask spread in the cross-section of stocks in the
prior day and re-run the analysis from Table 3. The panel shows that overall the sensitivity of
both volatility and turnover to the interaction of absolute mispricing and ETF ownership is
higher for stocks with a low spread. For the same level of mispricing and ETF ownership, the
impact on intraday volatility and turnover is lower for high bid-ask spread stocks. The only
exception to this pattern comes from the turnover of S&P 500 stocks.
We find additional evidence consistent with our conjecture when examining the effects
on intraday volatility and turnover of ETF flows (Table 7, Panel B). Similar to Panel A, we
regress intraday volatility and turnover on ETF ownership interacted with absolute ETF flows, as
well as main effects, controls, and fixed effects. We are interested in the way the coefficient on
33
(-4.062*0.019-222.293*0.019*0.019) = –0.1566%.
29
the interaction varies across columns. The sample is split by bid-ask spread, with odd columns
containing stocks with below-median spreads and even columns containing stocks with above-
median spreads. The results show that in most regression pairs, the effects are stronger for the
low bid-ask spread sample than for the high bid-ask spread sample. These results are consistent
with the idea that APs are reluctant to create/redeem shares when the costs of the transactions are
too high.
Next, we use stock lending fees as a proxy for limits to arbitrage. When the lending cost
is high, arbitrageurs are less likely to engage in arbitrage transactions, because the transaction
costs associated with short selling shares are higher, hence reducing the profitability of trades.
Also, a high lending fee can reflect a shortage in shares for lending, meaning that some
arbitrageurs may simply not be able to carry out the trade. Our prior is that the effects of
arbitrage trades on intraday volatility and turnover are expected to be stronger when lending fees
are lower.
Table 7, Panel C, presents evidence of this effect. For both intraday volatility and
turnover, the effect of absolute mispricing is weaker, for a given level of ETF ownership, when
lending fees are higher (even-numbered columns). In other words, when stock lending fees are
high, ETF ownership does not increase intraday volatility as much for a given level of
mispricing.
To provide evidence that APs’ trades are also affected by the cost of shorting, we split the
sample by lending fees and repeat the tests for fund flows. The results are presented in Table 7,
Panel D. Again, we are interested in the coefficient on the interaction between ETF ownership
and the absolute measure of fund flows. Consistent with our prior, the results show that in all
specifications the effect is stronger for the subsample that has low lending fees (odd-numbered
columns).
Overall, these results validate our claim that arbitrage is the channel through which ETFs
impact stock volatility and turnover. Whenever arbitrage is more costly, as signaled by a higher
bid-ask spread or steeper stock lending fees, the impact of our arbitrage proxies is reduced.
30
6 Conclusion
ETF prices are tied through arbitrage to the prices of the securities in their baskets
because they represent claims to the same stream of cash flows. In this paper, we present
evidence that arbitrage activity between ETFs and the stocks in their baskets leads to an increase
in stock volatility. We conclude that the liquidity shocks in the ETF market are propagated via
arbitrage trades to the prices of underlying securities, adding a new layer of non-fundamental
volatility.
Our identification strategy is based on the cross-sectional and time series variation in
ETF stock ownership. This variation is exogenous with respect to the variables of interest
because it arises from the mechanical weighting schemes of the indexes that are tracked by ETFs
and from the fact that assets under management change over time and across ETFs.
Our main finding is that stocks with higher ETF ownership display higher volatility and
turnover. A one standard deviation increase in ETF ownership raises daily volatility and turnover
by about 16%. We explore the economic channel behind these effects using two proxies for
arbitrage trading. First, when the price of ETFs and the underlying baskets diverge, there is a
stronger incentive for market participants to arbitrage the difference in prices. We show that
stock volatility and turnover indeed increase with the magnitude of this arbitrage opportunity.
Second, we use ETF share creation/redemption as a proxy for arbitrage trades. The rationale is
that market makers in the ETF market profit from deviations between the ETF price and the
NAV by changing the supply of ETF shares. We find that when ETF shares change in either
direction, there is a positive impact on stock volatility and turnover. Moreover, the effect of
arbitrage trades on the variables of interest is weaker for stocks that are harder to arbitrage, that
is, those with higher bid-ask spreads and higher costs of shorting. This evidence corroborates the
arbitrage channel as an explanation for the impact of ETFs on the underlying stocks. Finally, we
show that the price impact of ETF arbitrage reverts over a multiday horizon, consistent with the
initial trigger of the price move being, at least in part, a liquidity shock.
These results emphasize an unintended consequence of financial innovation. New
securities with values that are derived from existing securities, such as ETFs, are attractive for
arbitrage trades. Liquidity trading in the ETFs generates volatility that is passed down via
arbitrage to the underlying securities. While the effects that we point out are obtained in the
31
universe of U.S. stocks, we believe that they can be extended to other asset classes. In this sense,
our work relates to a growing literature highlighting the role of index trading in generating non-
fundamental volatility and comovement (e.g., Basak and Pavlova (2013)).
32
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Appendix. Variable Description
Variable Description Source
Daily Sample
ETF ownership
The sum of the ownership by all ETFs holding the stock, using the
most recent quarterly investment company reports for equity
ETFs.
Thomson-
Reuters
log(Mktcap) The logged market capitalization of the stock (in $ millions) at the
end of the day.
CRSP
1/Price The inverse of the nominal share price at the end of the day. CRSP
Amihud ratio Absolute return scaled by dollar volume in $million. CRSP
Bid-ask spread The quoted spread divided by the bid-ask midpoint. CRSP
Intraday volatility Standard deviation of second-by-second intraday returns. TAQ
Daily turnover Total share volume scaled by period-end shares outstanding, after
adjusting both volume and shares outstanding for splits and similar
events.
CRSP
abs(ETF
mispricing)
Stock-day level measure. Weighted average of the absolute
percentage difference between the ETF Price and the NAV across
the ETFs holding the stock (using the ETF price and NAV at 4:00
pm). The weight is ETF ownership of the stock.
TAQ,
Bloomberg,
Compustat
abs(ETF flows) Stock-day level measure. Weighted average of the absolute
percentage change in ETF shares outstanding across the ETFs
holding the stock. The weight is ETF ownership of the stock.
Bloomberg,
Compustat
Ret(t1, t2) The total return of the stock between the close of t1 and the close
of t2.
CRSP
Lending Fee Loan fee aggregated at the security level, 7-day average. Markit
Monthly Sample
ETF mispricing
volatility (within
the month)
Standard deviation of day-end ETF mispricing (using the ETF
price and NAV at 4:00 pm).
TAQ,
Bloomberg,
Compustat
ETF flow
volatility (within
the month)
Standard deviation of the relative change in daily ETF shares
outstanding during the month.
Bloomberg,
Compustat
log(Mktcap) The logged market capitalization of the stock (in $ millions) at the
end of the month.
CRSP
1/Price The inverse of the nominal share price at the end of the month. CRSP
Amihud Absolute return scaled by dollar volume in $million, average. CRSP
Bid-ask spread The quoted spread divided by the bid-ask midpoint. CRSP
36
Table 1. ETF Ownership Statistics
The table presents descriptive statistics for ETF ownership of stocks. For each year, across months and stocks, we
average the number of ETFs, their assets under management (AUM), the weight of each stock in the ETF, and the
percentage of each stocked owned by ETFs. We present statistics for S&P 500 stocks (left columns) and for Russell
3000 stocks (right columns).
Average Average stock Average ownership Average Average stock Average ownership
Year #ETFs ETF AUM ($m) weight in ETF (%) of ETF in firm (%) #ETFs ETF AUM ($m) weight in ETF (%) of ETF in firm (%)
2000 2.45 5627.93 0.64 0.27 2.41 5129.91 0.53 0.30
2001 13.45 2173.41 0.42 0.63 8.91 1053.93 0.16 0.37
2002 15.47 2798.87 0.45 0.88 10.18 1185.35 0.14 0.71
2003 15.95 3542.45 0.45 1.00 10.42 1465.49 0.14 0.85
2004 21.40 3451.84 0.47 1.06 14.30 1702.26 0.14 1.11
2005 24.74 3756.30 0.49 1.37 15.73 2040.02 0.16 1.37
2006 25.80 4337.34 0.51 1.68 16.81 2447.86 0.17 1.85
2007 36.04 4082.81 0.64 1.97 22.60 2438.93 0.24 2.17
2008 50.61 2980.85 0.69 2.69 30.26 1789.13 0.28 2.81
2009 53.19 2733.88 0.67 3.11 31.30 1710.54 0.26 3.41
2010 52.04 3261.34 0.68 3.16 30.08 2311.04 0.27 3.60
2011 52.77 3977.15 0.67 3.52 28.87 2937.45 0.27 3.77
2012 48.59 5026.84 0.68 3.78 26.93 3434.84 0.26 3.82
Average 30.43 3547.27 0.57 1.90 20.01 2045.99 0.21 2.10
S&P 500 Russell 3000
37
Table 2. Summary Statistics
The table presents summary statistics for the variables used in the study. Panels A and B show summary statistics
for the stock-day and for the stock-month samples, respectively. Panel C shows summary statistics for the return
regressions (returns are in percentages). Panel D provides correlations. All panels distinguish between the S&P 500
and the Russell 3000 samples.
Panel A: Daily Frequency Sample Statistics
Panel B: Monthly Frequency Sample Statistics
S&P 500
N Mean Std Dev Min Median Max
Intraday volatility (%) 1,480,640 0.022 0.018 0.004 0.016 0.147
Intraday turnover (%) 1,480,640 0.970 0.853 0.031 0.700 6.230
ETF ownership 1,480,640 0.019 0.014 0.000 0.016 0.092
abs(ETF mispricing) 1,480,640 0.002 0.013 0.000 0.001 3.960
abs(ETF flows) 1,480,640 0.008 0.025 0.000 0.005 7.370
log(Mktcap ($m)) 1,480,640 9.270 1.130 5.040 9.170 13.400
1/Price 1,480,640 0.041 0.038 0.001 0.031 0.870
Amihud 1,480,640 0.0004 0.0009 0.0000 0.0002 0.0315
Bid-ask spread 1,480,640 0.003 0.006 0.000 0.001 0.098
Russell 3000
N Mean Std Dev Min Median Max
Intraday volatility (%) 7,712,862 0.025 0.020 0.004 0.019 0.147
Intraday turnover (%) 7,712,862 0.874 0.875 0.029 0.596 6.230
ETF ownership 7,712,862 0.021 0.018 0.000 0.016 0.092
abs(ETF mispricing) 7,712,862 0.009 0.055 0.000 0.001 42.300
abs(ETF flows) 7,712,862 0.013 0.080 0.000 0.006 87.600
log(Mktcap ($m)) 7,712,862 7.000 1.540 0.616 6.760 13.400
1/Price 7,712,862 0.081 0.117 0.000 0.050 40.000
Amihud 7,712,862 0.020 0.055 0.000 0.003 0.965
Bid-ask spread 7,712,862 0.004 0.006 0.000 0.002 0.379
S&P 500
N Mean Std Dev Min Median Max
Daily stock volatility (%) 51,349 2.080 1.290 0.612 1.730 10.800
ETF ownership (%; average within the month) 51,349 2.110 1.440 0.050 1.760 9.360
ETF flows volatility (within the month) 51,349 0.045 0.045 0.001 0.033 0.433
ETF mispricing volatility (within the month) 51,349 0.003 0.003 0.000 0.002 0.021
Russell 3000
N Mean Std Dev Min Median Max
Daily stock volatility (%) 311,079 2.610 1.490 0.612 2.240 10.800
ETF ownership (%; average within the month) 311,079 2.320 1.730 0.017 1.880 9.380
ETF flows volatility (within the month) 311,079 0.062 0.055 0.001 0.047 0.435
ETF mispricing volatility (within the month) 311,079 0.003 0.003 0.000 0.003 0.021
38
Table 2. Summary Statistics (Cont.)
Panel C: Summary Statistics for Return Regressions
Panel D: Correlation Table
S&P 500
N Mean Std Dev Min Median Max
Ret(t) 1,444,095 0.053 2.152 -9.442 0.015 10.388
Ret(t+1,t+5) 1,444,095 0.203 4.655 -19.902 0.220 21.317
Ret(t+1,t+10) 1,444,095 0.386 6.304 -23.861 0.462 25.227
Ret(t+1,t+20) 1,444,095 0.750 8.858 -31.429 0.960 33.667
net(ETF Mispricing) 1,444,095 0.000 0.012 -0.908 0.000 3.919
net(ETF Flows) 1,444,095 0.001 0.019 -9.000 0.000 0.897
Russell 3000
N Mean Std Dev Min Median Max
Ret(t) 7,265,787 0.051 2.526 -9.443 0.000 10.388
Ret(t+1,t+5) 7,265,787 0.177 5.432 -19.902 0.147 21.318
Ret(t+1,t+10) 7,265,787 0.347 7.310 -23.862 0.351 25.227
Ret(t+1,t+20) 7,265,787 0.670 10.317 -31.429 0.749 33.668
net(ETF Mispricing) 7,265,787 -0.007 0.057 -42.325 0.000 27.620
net(ETF Flows) 7,265,787 0.001 0.051 -9.000 0.000 0.917
S&P 500
Intraday volatility Intraday turnover ETF ownership abs(ETF mispricing) abs(ETF flows) log(Mktcap) 1/Price Amihud
Intraday volatility 1.000
Intraday turnover 0.390 1.000
ETF ownership -0.011 0.375 1.000
abs(ETF mispricing) 0.046 -0.006 -0.071 1.000
abs(ETF flows) 0.026 0.023 -0.011 0.047 1.000
log(Mktcap) -0.086 -0.217 -0.067 -0.022 0.008 1.000
1/Price 0.436 0.141 -0.030 0.013 -0.003 -0.391 1.000
Amihud 0.175 -0.076 -0.192 0.031 0.010 -0.484 0.393 1.000
Bid-ask spread 0.213 -0.151 -0.409 0.048 0.016 -0.167 0.199 0.403
Russell 3000
Intraday volatility Intraday turnover ETF ownership abs(ETF mispricing) abs(ETF flows) log(Mktcap) 1/Price Amihud
Intraday volatility 1.000
Intraday turnover 0.271 1.000
ETF ownership -0.070 0.180 1.000
abs(ETF mispricing) -0.014 -0.037 -0.075 1.000
abs(ETF flows) 0.015 0.004 -0.016 0.184 1.000
log(Mktcap) -0.273 0.119 0.006 -0.068 -0.035 1.000
1/Price 0.440 -0.044 -0.025 0.003 0.006 -0.393 1.000
Amihud 0.271 -0.210 -0.157 0.011 0.007 -0.436 0.419 1.000
Bid-ask spread 0.279 -0.177 -0.326 0.082 0.008 -0.256 0.312 0.478
39
Table 3. ETF Ownership, Intraday Stock Volatility, and Turnover (Daily Sample)
The table reports estimates from OLS regressions of intraday volatility and daily turnover on ETF ownership and
controls. In Columns (1) to (4), the sample consists of S&P 500 stocks, and in Columns (5) to (8) the sample
consists of Russell 3000 stocks. The frequency of the observations is daily. Intraday stock volatility is computed
using second-by-second data from the TAQ database, and daily turnover is computed as daily volume from CRSP
divided by shares outstanding. Variable descriptions are provided in the Appendix. Standard errors are clustered at
the stock level. t-statistics are presented in parentheses. ***
, **
, and * represent statistical significance at the 1%, 5%,
and 10% levels, respectively.
Sample:
Dependent variable:
(1) (2) (3) (4) (5) (6) (7) (8)
ETF ownership (t-1) 0.333*** 0.243*** 18.869*** 11.631*** -0.009 0.069*** 7.624*** 4.026***
(9.613) (7.461) (7.976) (8.773) (-1.360) (8.883) (14.875) (10.027)
log(Mktcap (t-1)) 0.003*** 0.004*** -0.171*** -0.194*** -0.001*** -0.003*** 0.034*** 0.077***
(8.781) (5.356) (-10.524) (-5.552) (-12.372) (-10.781) (6.106) (9.068)
1/Price (t-1) 0.219*** 0.195*** 2.826*** 1.202** 0.059*** 0.032*** 0.534*** -0.044
(20.998) (12.929) (6.106) (2.263) (26.912) (12.631) (12.861) (-1.048)
Amihud (t-1) -0.243 -0.333 -158.086*** -123.183*** 0.015*** 0.020*** -2.551*** -1.141***
(-0.554) (-1.038) (-7.861) (-7.548) (6.206) (8.656) (-26.777) (-15.669)
Bid-ask spread (t-1) -0.124 -0.119* -9.143*** -7.636*** -0.033 -0.006 -12.764*** -10.096***
(-1.496) (-1.872) (-4.773) (-5.516) (-1.211) (-0.264) (-12.396) (-13.161)
Stock fixed effects No Yes No Yes No Yes No Yes
Day fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Observations 1,472,346 1,472,346 1,472,346 1,472,346 7,687,652 7,687,652 7,687,652 7,687,652
Adjusted R2
0.425 0.466 0.282 0.464 0.367 0.451 0.123 0.381
S&P 500 Russell 3000
Intraday volatility Intraday volatilityIntraday turnover Intraday turnover
40
Table 4. ETF Ownership and Daily Stock Volatility (Monthly Sample)
The table reports estimates from OLS regressions of daily volatility on ETF ownership, ETF mispricing volatility,
and ETF flow volatility. In Columns (1) to (3), the sample consists of S&P 500 stocks, and in Columns (4) to (6),
the sample consists of Russell 3000 stocks. The frequency of the observations is monthly. Daily stock volatility is
computed using daily returns within a month. Variable descriptions are provided in the Appendix. Standard errors
are clustered at the date and stock levels. t-statistics are presented in parentheses. ***
, **
, and * represent statistical
significance at the 1%, 5%, and 10% levels, respectively.
Dependent variable:
Sample:
(1) (2) (3) (4) (5) (6)
ETF ownership (average within the month) 0.144*** 0.041***
(8.190) (7.051)
ETF mispricing volatility (within the month) 94.223*** 25.973***
(12.654) (10.378)
ETF flow volatility (within the month) 3.757*** 0.939***
(11.170) (9.953)
log(Mktcap (t-1)) -0.159*** -0.159*** -0.170*** -0.259*** -0.258*** -0.261***
(-2.917) (-3.069) (-3.168) (-12.444) (-12.544) (-12.666)
1/Price (t-1) 6.494*** 6.180*** 6.431*** 2.750*** 2.693*** 2.695***
(7.250) (7.074) (7.237) (11.937) (11.802) (11.764)
Amihud (t-1) 87.364*** 85.146*** 84.791*** 0.453* 0.518* 0.503*
(4.256) (4.297) (4.226) (1.646) (1.891) (1.833)
Bid-ask spread (t-1) 23.586** 38.094*** 21.167** 3.692 5.364 3.336
(2.454) (4.359) (2.156) (1.078) (1.583) (0.969)
Stock Effects Yes Yes Yes Yes Yes Yes
Time Effects Yes Yes Yes Yes Yes Yes
Observations 51,349 51,349 51,349 311,079 311,079 311,079
Adjusted R2
0.630 0.638 0.630 0.557 0.557 0.557
S&P 500 Russell 3000
Daily stock volatility (computed within the month)
41
Table 5. Stock Volatility, ETF Ownership, and Arbitrage
The table reports estimates from OLS regressions of intraday volatility and daily turnover on ETF ownership,
variables that proxy for ETF arbitrage, and controls. In Columns (1) to (2), the sample consists of S&P 500 stocks,
and in Columns (3) to (4), the sample consists of Russell 3000 stocks. The frequency of the observations is daily.
Intraday stock volatility is computed using second-by-second data from the TAQ database, and daily turnover is
computed as daily volume from CRSP divided by shares outstanding. In Panel A, the variable of interest is the
interaction of lagged absolute ETF mispricing and ETF ownership. In Panel B, the variable of interest is the
interaction of lagged absolute ETF fund flows and ETF ownership. Variable descriptions are provided in the
Appendix. Standard errors are clustered at the stock level. t-statistics are presented in parentheses. ***
, **
, and *
represent statistical significance at the 1%, 5%, and 10% levels, respectively.
Panel A: Effect of ETF Mispricing on Volatility and Turnover
Sample:
Dependent variable: Intraday volatility Intraday turnover Intraday volatility Intraday turnover
(1) (2) (3) (4)
ETF ownership (t-1) 0.186*** 10.371*** 0.068*** 4.005***
(5.814) (8.038) (8.633) (9.949)
× abs(ETF mispricing (t-1)) 42.035*** 896.893*** -0.113 -2.660
(9.876) (6.860) (-0.417) (-0.350)
abs(ETF mispricing (t-1)) 0.006*** 0.207** -0.005 -0.085
(2.749) (2.459) (-0.943) (-0.811)
log(Mktcap (t-1)) 0.004*** -0.198*** -0.003*** 0.071***
(5.351) (-5.658) (-11.660) (8.253)
1/Price (t-1) 0.193*** 1.145** 0.032*** -0.062
(12.832) (2.148) (12.693) (-1.454)
Amihud (t-1) -0.306 -122.456*** 0.020*** -1.153***
(-0.960) (-7.536) (8.404) (-15.860)
Bid-ask spread (t-1) -0.096 -7.187*** 0.004 -9.967***
(-1.595) (-5.328) (0.187) (-13.096)
Stock fixed effects Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes
Observations 1,471,139 1,471,139 7,679,072 7,679,072
Adjusted R2
0.470 0.465 0.452 0.381
S&P 500 Russell 3000
42
Table 5. Stock Volatility, ETF Ownership, and Arbitrage (Cont.)
Panel B: Effects of Fund Flows on Volatility and Turnover
Sample:
Dependent variable: Intraday volatility Intraday turnover Intraday volatility Intraday turnover
(1) (2) (3) (4)
ETF ownership (t-1) 0.229*** 10.305*** 0.068*** 3.328***
(7.003) (7.996) (8.846) (8.269)
× abs(ETF flows (t)) 3.197*** 232.101*** 0.141* 70.306***
(5.861) (5.988) (1.688) (8.298)
abs(ETF flows (t)) -0.009*** -0.090 -0.000* -0.129***
(-4.521) (-1.491) (-1.893) (-3.466)
log(Mktcap (t-1)) 0.004*** -0.198*** -0.003*** 0.073***
(5.240) (-5.709) (-11.581) (8.520)
1/Price (t-1) 0.194*** 1.120** 0.032*** -0.063
(12.769) (2.130) (12.692) (-1.490)
Amihud (t-1) -0.302 -121.598*** 0.020*** -1.137***
(-0.951) (-7.525) (8.458) (-15.699)
Bid-ask spread (t-1) -0.112* -7.565*** 0.003 -9.946***
(-1.792) (-5.532) (0.119) (-13.088)
Stock fixed effects Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes
Observations 1,471,139 1,471,139 7,679,072 7,679,072
Adjusted R2
0.467 0.466 0.452 0.381
S&P 500 Russell 3000
43
Table 6. Price Reversals
The table reports estimates from OLS regressions of one- and multiday returns on ETF ownership, variables that
proxy for ETF arbitrage, and controls. In Columns (1) to (4), the sample consists of S&P 500 stocks, and in
Columns (5) to (8), the sample consists of Russell 3000 stocks. The frequency of the observations is daily. Returns
are in percent. In Panel A, the variable of interest is the interaction of ETF mispricing and ETF ownership. In Panel
B, the variable of interest is the interaction of ETF fund flows and ETF ownership. Variable descriptions are
provided in the Appendix. Standard errors are clustered at the stock level. t-statistics are presented in parentheses. ***
, **
, and * represent statistical significance at the 1%, 5%, and 10% levels, respectively.
Panel A: Price Reversals Following ETF Mispricing
Ret(t) Ret(t+1,t+5) Ret(t+1,t+10) Ret(t+1,t+20) Ret(t) Ret(t+1,t+5) Ret(t+1,t+10) Ret(t+1,t+20)
(1) (2) (3) (4) (5) (6) (7) (8)
ETF ownership (t-1) 0.662*** -2.630*** -5.866*** -10.678*** 0.013 -0.487 -0.792 -0.709
(3.410) (-2.901) (-3.316) (-3.048) (0.184) (-1.642) (-1.360) (-0.615)
× ETF mispricing (t-1) 321.266*** -492.213*** -308.665 -1,421.138** -8.326*** -15.234 -17.098 -19.997
(3.615) (-2.929) (-1.061) (-2.519) (-3.599) (-1.345) (-0.766) (-0.486)
ETF mispricing (t-1) 1.043*** 0.232 -1.614*** -1.671** -0.000 -0.158 -0.390 -0.793
(3.843) (0.593) (-3.331) (-2.359) (-0.007) (-1.021) (-1.188) (-1.237)
log(Mktcap (t-1)) 0.014*** -0.038*** -0.079*** -0.142*** 0.014*** 0.004 0.011** 0.025**
(6.339) (-4.608) (-4.749) (-4.327) (13.903) (1.291) (1.970) (2.219)
1/Price (t-1) -1.025*** 1.053*** 2.201*** 5.919*** -0.615*** -0.324*** -0.496*** -0.322
(-9.677) (2.838) (2.965) (4.105) (-20.951) (-5.709) (-4.604) (-1.520)
Amihud (t-1) 28.351*** -19.831 -48.022* -50.814 0.099*** -1.377*** -2.530*** -4.371***
(6.601) (-1.567) (-1.874) (-1.095) (2.864) (-12.425) (-12.094) (-10.679)
Bid-ask spread (t-1) 2.025*** 1.423 4.986 10.859 2.159*** -2.294** -2.840 -5.372
(3.363) (0.625) (1.128) (1.299) (6.012) (-1.986) (-1.337) (-1.312)
Stock fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Observations 1,426,141 1,426,141 1,426,141 1,426,141 7,090,277 7,090,277 7,090,277 7,090,277
Adjusted R2
0.325 0.299 0.278 0.281 0.281 0.246 0.223 0.223
S&P 500 Russell 3000
44
Table 6. Price Reversals (Cont.)
Panel B: Price Reversals Following Fund Flows to ETFs
Ret(t) Ret(t+1,t+5) Ret(t+1,t+10) Ret(t+1,t+20) Ret(t) Ret(t+1,t+5) Ret(t+1,t+10) Ret(t+1,t+20)
(1) (2) (3) (4) (5) (6) (7) (8)
ETF ownership (t-1) 0.612*** -2.453*** -5.658*** -10.313*** 0.070 -0.382 -0.648 -0.482
(3.124) (-2.705) (-3.186) (-2.941) (0.999) (-1.289) (-1.113) (-0.419)
× ETF flows (t) 16.245* -134.935*** -237.910*** -222.293*** -49.383*** -46.006*** -40.958*** -58.873***
(1.878) (-5.034) (-8.528) (-5.830) (-14.948) (-8.489) (-6.047) (-6.711)
ETF flows (t) 0.255* -1.689*** -2.894*** -4.062*** 0.067*** -0.117*** -0.087* -0.036
(1.942) (-3.104) (-5.232) (-4.629) (3.743) (-3.081) (-1.795) (-0.558)
log(Mktcap (t-1)) 0.015*** -0.039*** -0.079*** -0.144*** 0.014*** 0.003 0.009* 0.022**
(6.870) (-4.665) (-4.774) (-4.389) (13.831) (0.972) (1.673) (2.013)
1/Price (t-1) -1.003*** 1.016*** 2.148*** 5.752*** -0.616*** -0.326*** -0.500*** -0.333
(-9.568) (2.744) (2.897) (4.007) (-20.987) (-5.750) (-4.638) (-1.574)
Amihud (t-1) 30.337*** -17.901 -44.859* -45.831 0.098*** -1.396*** -2.557*** -4.423***
(7.039) (-1.408) (-1.727) (-0.990) (2.850) (-12.642) (-12.265) (-10.843)
Bid-ask spread (t-1) 1.826*** 1.298 4.924 11.176 2.107*** -2.160* -2.547 -4.910
(3.047) (0.574) (1.120) (1.338) (5.835) (-1.871) (-1.201) (-1.201)
Stock fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Observations 1,419,903 1,419,903 1,419,903 1,419,903 7,078,529 7,078,529 7,078,529 7,078,529
Adjusted R2
0.326 0.299 0.279 0.281 0.281 0.246 0.223 0.223
S&P 500 Russell 3000
45
Table 7. Evidence from Limits-to-Arbitrage
The table reports estimates from OLS regressions of intraday volatility and daily turnover on ETF ownership,
variables that proxy for ETF arbitrage, and controls. In Columns (1) to (4), the sample consists of S&P 500 stocks,
and in Columns (5) to (8), the sample consists of Russell 3000 stocks. The frequency of the observations is daily.
Intraday stock volatility is computed using second-by-second data from the TAQ database, and daily turnover is
computed as daily volume from CRSP divided by shares outstanding. In Panels A and C, the variable of interest is
the interaction of lagged absolute ETF mispricing and ETF ownership. In Panels B and D, the variable of interest is
the interaction of lagged absolute ETF fund flows and ETF ownership. The sample is split by the lagged bid-ask
spread (Panels A and B) or the lagged stock lending fee (Panels C and D). Variable descriptions are provided in the
Appendix. Standard errors are clustered at the stock level. t-statistics are presented in parentheses. ***
, **
, and *
represent statistical significance at the 1%, 5%, and 10% levels, respectively.
Panel A: Mispricing and Bid-Ask Spread
Sample:
Dependent variable:
Bid-ask spread (t-1): Low High Low High Low High Low High
(1) (2) (3) (4) (5) (6) (7) (8)
ETF ownership (t-1) 0.142*** 0.168*** 10.017*** 8.286*** 0.094*** 0.066*** 3.564*** 4.195***
(4.833) (4.169) (7.050) (5.462) (8.944) (7.257) (6.480) (9.764)
× abs(ETF mispricing (t-1)) 50.828*** 17.244*** 750.869*** 764.789*** 0.736*** -0.197 21.775** -11.773*
(12.241) (5.869) (5.204) (5.591) (3.767) (-0.955) (2.227) (-1.956)
abs(ETF mispricing (t-1)) 0.003 0.001 0.204** -0.266 -0.016*** -0.003 -0.429*** -0.007
(1.388) (0.189) (2.149) (-1.487) (-4.880) (-0.753) (-3.018) (-0.118)
log(Mktcap (t-1)) 0.005*** 0.002** -0.186*** -0.295*** 0.000* -0.005*** -0.037*** 0.083***
(4.044) (2.541) (-5.012) (-7.028) (1.780) (-15.029) (-2.982) (8.354)
1/Price (t-1) 0.082*** 0.190*** -0.985 0.363 0.062*** 0.026*** -1.590*** 0.028
(3.555) (12.505) (-1.327) (0.679) (10.606) (10.371) (-6.486) (0.804)
Amihud (t-1) -0.467 -0.222 -213.891***-98.507*** 0.048*** 0.014*** -3.218*** -0.937***
(-0.866) (-0.524) (-7.192) (-6.234) (7.150) (6.353) (-10.700) (-16.194)
Bid-ask spread (t-1) -0.641*** 0.119** -14.885*** -3.711** -0.685*** 0.081*** -10.460*** -6.150***
(-5.013) (2.500) (-5.906) (-2.471) (-8.990) (3.718) (-4.387) (-9.479)
Stock fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Observations 735,570 735,569 735,570 735,569 3,839,536 3,839,536 3,839,536 3,839,536
Adjusted R2
0.488 0.522 0.544 0.436 0.407 0.474 0.401 0.362
S&P 500 Russell 3000
Intraday volatility Intraday turnover Intraday volatility Intraday turnover
46
Table 7. Evidence from Limits to Arbitrage (Cont.)
Panel B: Fund Flows and Bid-Ask Spread
Sample:
Dependent variable:
Bid-ask spread (t-1): Low High Low High Low High Low High
(1) (2) (3) (4) (5) (6) (7) (8)
ETF ownership (t-1) 0.205*** 0.169*** 9.918*** 7.760*** 0.099*** 0.064*** 3.023*** 3.562***
(6.813) (4.262) (6.834) (5.344) (9.495) (7.130) (5.581) (8.188)
× abs(ETF flows (t)) 4.231*** 2.648*** 275.046*** 197.370*** -0.096 0.239** 74.942*** 55.122***
(7.632) (4.580) (9.243) (4.609) (-0.979) (2.456) (12.255) (6.068)
abs(ETF flows (t)) -0.010*** -0.004** -0.095 -0.037 0.000* -0.001*** 0.018 -0.133***
(-4.051) (-2.004) (-1.606) (-0.404) (1.691) (-2.949) (1.536) (-9.671)
log(Mktcap (t-1)) 0.005*** 0.002** -0.186*** -0.294*** 0.001* -0.005*** -0.034*** 0.084***
(3.997) (2.547) (-5.094) (-7.066) (1.898) (-14.978) (-2.725) (8.478)
1/Price (t-1) 0.086*** 0.190*** -0.949 0.338 0.062*** 0.026*** -1.590*** 0.026
(3.633) (12.430) (-1.284) (0.637) (10.610) (10.370) (-6.478) (0.764)
Amihud (t-1) -0.484 -0.204 -213.397***-97.238*** 0.047*** 0.014*** -3.147*** -0.928***
(-0.868) (-0.481) (-7.212) (-6.185) (7.068) (6.410) (-10.486) (-16.103)
Bid-ask spread (t-1) -0.683*** 0.116** -15.357*** -3.831** -0.695*** 0.080*** -10.444*** -6.132***
(-5.086) (2.440) (-5.970) (-2.569) (-9.083) (3.689) (-4.357) (-9.464)
Stock fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Observations 735,568 735,571 735,568 735,571 3,839,536 3,839,536 3,839,536 3,839,536
Adjusted R2
0.482 0.522 0.545 0.438 0.407 0.474 0.401 0.362
S&P 500 Russell 3000
Intraday volatility Intraday turnover Intraday volatility Intraday turnover
47
Table 7. Evidence from Limits to Arbitrage (Cont.)
Panel C: Mispricing and Lending Fees
Sample:
Dependent variable:
Lending fees: Low High Low High Low High Low High
(1) (2) (3) (4) (5) (6) (7) (8)
ETF ownership (t-1) 0.085*** 0.026* 6.587*** 5.601*** 0.037*** 0.044*** 2.813*** 1.969***
(5.327) (1.854) (5.845) (5.076) (8.026) (7.162) (6.827) (4.164)
× abs(ETF mispricing (t-1)) 21.480*** 18.856*** 1,467.626*** 783.211*** 2.221*** -0.536*** 324.516*** -2.942
(5.072) (4.503) (5.320) (3.807) (2.606) (-2.767) (3.950) (-0.557)
abs(ETF mispricing (t-1)) -0.157* -0.224*** -16.278*** -8.800** -0.035* 0.002*** -7.344*** 0.019
(-1.657) (-2.952) (-2.904) (-2.084) (-1.772) (3.862) (-3.835) (1.079)
log(Mktcap (t-1)) 0.000 0.001 -0.464*** -0.566*** -0.004*** -0.006*** -0.007 0.033*
(0.525) (1.214) (-11.998) (-10.087) (-14.197) (-16.838) (-0.391) (1.772)
1/Price (t-1) 0.187*** 0.204*** 0.038 1.338 0.035*** 0.015*** -0.416*** -0.064
(13.798) (15.204) (0.058) (1.254) (12.870) (5.077) (-4.354) (-1.058)
Amihud (t-1) -0.491 -0.662 -273.758*** -407.072*** -0.010*** -0.018*** -1.437*** -1.435***
(-0.693) (-0.848) (-5.798) (-6.412) (-3.445) (-5.086) (-10.874) (-10.162)
Bid-ask spread (t-1) 1.777*** 2.183*** 47.114*** 44.975*** 1.026*** 1.372*** -13.974*** -15.849***
(3.117) (4.903) (4.595) (3.088) (11.298) (13.376) (-6.540) (-5.944)
Stock fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Observations 366,618 366,618 366,618 366,618 2,088,566 2,088,563 2,088,566 2,088,563
Adjusted R2
0.518 0.582 0.504 0.524 0.477 0.520 0.458 0.428
S&P 500 Russell 3000
Intraday volatility Intraday turnover Intraday volatility Intraday turnover
48
Table 7. Evidence from Limits to Arbitrage (Cont.)
Panel D: Fund Flows and Lending Fees
Sample:
Dependent variable:
Lending fees: Low High Low High Low High Low High
(1) (2) (3) (4) (5) (6) (7) (8)
ETF ownership (t-1) 0.107*** 0.047*** 7.899*** 6.312*** 0.034*** 0.040*** 2.321*** 1.200**
(6.442) (3.128) (7.013) (5.739) (7.370) (6.541) (6.005) (2.510)
× abs(ETF flows (t)) 0.953 0.263 98.639** 48.965 0.684*** 0.375*** 100.294*** 83.037***
(1.639) (0.753) (2.485) (1.234) (7.212) (4.292) (12.066) (6.767)
abs(ETF flows (t)) 0.039** 0.046*** 1.079 2.848*** -0.002 -0.001*** -0.856*** -0.250***
(2.560) (4.979) (0.977) (2.781) (-0.612) (-3.837) (-3.278) (-7.415)
log(Mktcap (t-1)) 0.000 0.001 -0.467*** -0.564*** -0.004*** -0.006*** -0.005 0.036*
(0.404) (1.257) (-12.144) (-10.088) (-14.128) (-16.803) (-0.305) (1.948)
1/Price (t-1) 0.187*** 0.204*** 0.015 1.323 0.035*** 0.015*** -0.411*** -0.064
(13.694) (15.195) (0.023) (1.248) (12.857) (5.076) (-4.336) (-1.059)
Amihud (t-1) -0.474 -0.627 -272.455*** -404.583*** -0.010*** -0.018*** -1.430*** -1.433***
(-0.665) (-0.795) (-5.891) (-6.440) (-3.409) (-5.074) (-10.902) (-10.234)
Bid-ask spread (t-1) 1.764*** 2.154*** 46.079*** 42.960*** 1.026*** 1.374*** -14.022*** -15.321***
(3.068) (4.840) (4.403) (2.967) (11.271) (13.377) (-6.622) (-5.800)
Stock fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Day fixed effects Yes Yes Yes Yes Yes Yes Yes Yes
Observations 366,618 366,618 366,618 366,618 2,088,566 2,088,563 2,088,566 2,088,563
Adjusted R2
0.518 0.582 0.503 0.524 0.477 0.520 0.459 0.429
S&P 500 Russell 3000
Intraday volatility Intraday turnover Intraday volatility Intraday turnover
49
Figure 1: Illustration of the Propagation of Non-fundamental Shocks Via Arbitrage
Figure 1a. Initial equilibrium Figure 1b. Non-fundamental shock to ETF
NAV
Fundamental Value
ETF NAV
Fundamental Value
ETF
NAV
Fundamental Value
ETF
Figure 1c. Initial outcome of arbitrage:
the non-fundamental shock is propagated
to the NAV, and the ETF price starts
reverting to the fundamental value.
NAV
Fundamental Value
ETF
Figure 1d. Re-establishment of equilibrium:
after some time, both the ETF price and the
NAV revert to the fundamental value.
50
Figure 2: Illustration of the Propagation of a Fundamental Shock with Price Discovery
Occurring in the ETF Market
Figure 2a. Initial equilibrium Figure 2b. Shock to fundamental value
NAV
Fundamental Value
ETF
New Fundamental Value
NAV ETF
NAV
ETF
Figure 2c. Price discovery takes place in
the ETF market. The ETF price moves to
the new fundamental value.
New Fundamental Value NAV ETF
Figure 2d. After a delay, the NAV
catches up with the new fundamental.
New Fundamental